Fire extinguishing composition comprising a fluoroaliphatic surfactant and a fluorine-free surfactant

ABSTRACT

COMPOSITIONS ARE DISCLOSED WHICH FORM TOUGH, DURABLE, RAPIDLY-FORMING AND SPREADING FILMS ON THE SURFACE OF HYDROCARBON LIQUIDS COMPRISING IN COMBINATION A WATERSOLUBLE FLUOROALIPHATIC SURFACTANT AND A WATER-SOLUBLE SYNTHETIC IMPUTRESCIBLE HYDROCARBON-CONGRUOUS ORGANIC FLUORINE-FREE SURFACTANT AND WATER. THE FILMS FORMED BY THESE COMPOSITIONS ARE ESPECIALLY EFFECTIVE IN SUPPRESSING THE VAPORIZATION OF HYDROCARBON LIQUIDS INTO THE AIR AND ARE, THEREFORE, USEFUL FOR EXTINGUISHING LIQUID HYDROCARBON FIRES.

Feb. 9, 1971 v. L.. FRANCEN 3,5656

FIRE EXTINGUISHING COMPOSITION COMPRISING A FLUOROALIPHATIC SURFACTANT AND A FLUORINE-FREE SURFACTANT Filed June 12, 1969 fm/@N @wwf/v United States Patent 3,562,156 FIRE EXTINGUISHING COMPOSITION COMPRIS- ING A FLUOROALIPHATIC SURFACTANT AND A FLUORINE-FREE SURFACTANT Vernon L. Francen, Roseville, Minn., assignor to Minne- Sota Mining and Manufacturing Company, St. Paul, Minn., a corporation of Delaware Continuation-in-part of application Ser. No. 722,630, Apr. 19, 1968. This application June 12, 1969, Ser. No. 840,102

Int. Cl. A62c 1/12; A62d 1/00 U.S. Cl. 252-8.05

ABSTRACT OF THE DISCLOSURE Compositions are `disclosed which form tough, durable, rapidly-forming and spreading films on the surface of hydrocarbon liquids comprising in combination a watersoluble fiuoroaliphatic surfactant and a water-soluble synthetic irnputrescible hydrocarbon-congruous organic fluorine-free surfactant and water. The films formed by these compositions are especially effective in suppressing the vaporization of hydrocarbon liquids into the air and are, therefore, useful for extinguishing liquid hydrocarbon fires.

COMPOSITION OF MATTER This application is a continuation-in-part of my application Ser. No. 722,630, filed Apr. 19, 1968 and now abandoned.

The present invention relates generally to compositions for the preparation of tough, durable, rapidly-forming and spreading films on hydrocarbon liquids comprising in combination a water-soluble uoroaliphatic surfactant, a water-soluble synthetic imputrescible hydrocarbon-congruous organic fiuorine-free surfactant and Water with or without a stabilizer. These films can be formed and spread over the surface of a volatile Water insoluble liquid to provide an effective barrier to vaporization of the volatile liquid into an adjacent volume of air.

At the present time, substantially more than 11/2 billion metric tons of petroleum products are produced annually. These materials find their way throughout the world in tanks, ships, trucks, railroad cars and pipelines to storage tanks, processing plants, and ultimately, to the consumer in drums, tanks, cans and bottles. Most of these petroleum products have a significant vapor pressure under the conditions of use and storage, and are thus continually evaporating into the air at each point of transfer, shipment and use. There are a number of obvious disadvantages to this free evaporation of volatile hydrocarbon materials. The simple economic loss may be significant; for example, in the handling of gasoline, the loss through evaporation between the refinery and the automobile can be as great as percent of the product. Of greater significance, perhaps, is the situation in an area such as Southern `California where the presence of large quantities of hydrocarbon materials in the air has been cited as a major factor in the smog problem. The evaporation losses occasioned in the processing and handling of petroleum products approaches the hydrocarbon output (combustion by-products) produced by automobiles. The most spectacular and pressing problem of free evaporation of hydrocarbon materials is the fire hazard involved. These materials are generally highly flammable and their vapors can form combustible mixtures with air. Adventitious sparks or other sources of ignition can result in a disastrous fire especially in the case of pipelines or large scale storage facilities. The threat of a major fire in a refinery tank farm, a service station, or on the decks or below deck areas of an aircraft carrier is an ever pres- 12 Claims ice ent hazard. Spills, whether resulting from an accidentally open valve, an overturned or broken container or an overturned tank truck, represent an immediate potential hazard. A positive, readily available, simply applied method for stopping the evaporation of flammable liquids under these conditions would represent a marked and significant improvement over present procedures.

It is accordingly an object of the present invention to provide compositions which can be used to form tough, durable, rapidly-forming and spreading vapor barrier films on hydrocarbon liquids.

Another object of the invention is to provide concentrated compositions which form water-containing surface films which inhibit the release of flammable vapors from a hydrocarbon liquid surface.

Other objects and advantages of the invention will become more fully apparent from the following detailed description.

The ability of surface films to minimize evaporation has long been known. Typically, a film, for example of cetyl alcohol, can be spread upon a reservoir in desert areas and cut the evaporation of water to one-half the evaporation level of water in the absence of the film. ln a 1962 publication (Guenthner and Victor, Industrial and Engineering Chemistry, September 1962, page 168) it was recognized that uorochemical compounds could be utilized to form barrier films for evaporation suppression on gasoline. The authors state that the addition of .003% fluorochemical can reduce the evaporation of the gasoline under static conditions to the point of nonflammability. The restriction to static conditions points out a very significant limitation to the effective use of such films. In order to be an effective evaporation suppressant, it is necessary that the barrier film be rapidly formed initially and again after disturbance, and that the film be sufficiently mobile and capable of remaining extended under conditions of motion so that it will establish and maintain a substantially continuous barrier. The iiuorochemical filmforming systems known up until now, have, however, formed films relatively slowly and have been incapable of maintaining or rapidly reestablishing a satisfactory barrier film after disruption by agitation.

A recent development related to the extinguishing of burning fuel, Tuve and Jablonski U.S. Pat. No. 3,258,423, is directed to films comprising water and specific fiuorochemicals to produce a film on the fuel surface which cuts down the rate of evaporation so that reignition becomes difiicult or impossible. This invention has resulted in the development of a fire extinguishing system vastly more efficient than any preceding methods. However, only a relatively few iiuorochemicals in relatively high concentrations can be used to form such aqueous films resulting in an undesirably high cost for the fire-fighting composition.

The compositions of the present invention form tough, mobile, rapidly spreading, readily healing vapor barrier films. They can be formulated with lower quantities of the more expensive fluorochemical component than was necessary to achieve equivalent results with prior systems. They can be stored as dilute aqueous solutions in readiness for use particularly for preventive applications, eg., prevention of fires from spilled fuels. More commonly, they will be distributed and stored as a concentrate which can be diluted at the time of use. A particularly desirable commercial item is a material which, at the time of use, would be diluted in the ratio of six volumes of concentrate to 94 volumes of water, i.e., diluted with about sixteen parts by volume of water. Standard commercially available mixing and dispensing equipment, e.g., fire-fighting equipment, is commonly available for this particular concentrate.

Many of the compositions, in addition to forming a vapor barrier lm, will, when mixed with large quantities of vaporized propellant or air, form relatively stable foams, particularly for the extinguishing of large fires. In some cases, it may be desirable to add an auxiliary foaming agent, such as a partially hydrolyzed protein, and/ or auxiliary agents such as foam stabilizers exemplified by high molecular weight polyoxyethylene glycol (e.g., Polyox) and an alkyl ether of an alkylene glycol (e.g., butoxy hydroxy-ethoxy ethane) or freeze resistant components (glycerol or ethylene glycol). Generally speaking, these compositions are compatible with solid re extinguishing agents such as powdered potassium bicarbonate.

The following tests and test procedures have been devised as convenient laboratory guides for determination of the performance characteristics of the various compositions. It has been found that compositions which passed these laboratory tests generally performed adequately in large scale field tests. Perhaps of'more significance is the fact that compositions which failed the laboratory tests did not perform acceptably in field tests.

It should be recognized that the test hydrocarbon fuel used herein, cyclohexane, is a relatively difcult substrate on which to form films. In general, aromatic hydrocarbons such as toluene or xylene or high-boiling aliphatic hydrocarbons such as gasoline, kerosene and fuel oil permit the formation of films at lower concentrations of surfactant. Accordingly, films formed on cyclohexane can be expected to be more effective films on the latter classes of hydrocarbons at any given surfactant concentration.

FILM FORMATION AND SPREADING TEST (l) Five drops of the test solution are placed in the center of a clean surface of cyclohexane contained in a 145 rnm. petri dish at about 25 C.

(2) By using reflected light, the time in seconds required for the applied solution to spread across the cyclohexane surface to the dish is measured (film speed).

SEAL TEST (l) Following Step 2 above, 15 additional drops of test solution are placed on the cyclohexane surface-distributed equally over the surface.

(2) Sixty seconds after the first of the additional l5 drops of test solution is added, a flame probe is passed (but not touching) overthe cyclohexane surface. This result is an indication of vapor sealing. About 5 seconds should elapse before vapor burning is observed.

BURNBACK RESISTANCE TEST (1) The flame probe is then touched to the cyclohexane surface near an edge until a spot of ignition is achieved.

(2) The time in seconds required to burn half way across the cyclohexane surface is measured (50% burnback). At least 2 seconds for 50% burnback is required for a composition to be considered a satisfactory extinguishing agent.

RESISTANCE TO AGITATION (1) This test consists of using the result of Step 1 of the seal test. A glass rod is used to agitate the fuel surface while a flame is held over the area of agitation (but not touching the fuel surface).

(2) The time to ignition of the fuel is noted.

The compositions of this invention comprise in combination a fluoroaliphatic surfactant, a water-soluble synthetic imputrescible hydrocarbon-congruous organic fluorine-free surfactant and water. The fluoroalphatic surfactant is a composition including in the same molecule both a fluoroaliphatic radical and a water solubilizing group, generally represented as RfQmZ. The particular structure of the uoroaliphatic surfactant is not critical; rather it is the balance of the physical properties of the compound that determines its usefulness for the purpose.

It is necessary that the combination of fluoroaliphatic radical and Water solubilizing group be so balanced as to provide a solubility in water at 25 C. of at least 0.01 percent by Weight. yIt is preferred, particularly in the case where a concentrate is prepared, that the solubility in water be at least about 0.15 percent by weight. In order to function effectively as a film-spreading agent, the surfactant must be suiciently surface active to provide a surface tension of less than about 28 dynes/cm., preferably less than 23 dynes/cm., in aqueous solution at a concentration of about 0.25% or less.

If the fluoroaliphatic surfactant is too soluble in hydrocarbon liquid, it will be extracted too rapidly from the aqueous film to provide suiciently durable coverage. In general, this requires the presence of at least about 20 percent by weight of fluorine, i.e., carbon bonded uorine, in the surfactant.

To possess these properties, the fluorinated aliphatic radical, Rf, can be Vgenerally described as a fluorinated saturated monovalent non-aromatic radical of at least 3 carbon atoms. The aliphatic chain may be straight, branched, or, if sufiiciently large, cyclic and may include oxygen or trivalent nitrogen atoms bonded only to carbon atoms. A fully fluorinated radical is preferred, but hydrogen or chlorine atoms may be present as substituents provided that not more than one atom of either is present for every two carbon atoms, and preferably, the radical contains at least a terminal perfluoromethyl group. While radicals containing a larger number of carbon atoms will function adequately, compounds containing not more than about 20 carbon atoms are preferred since larger radicals usually represent a less eflicient utilization of uorine than is possible with shorter chains. Fluoroaliphatic radicals containing about 5 to 12 carbon atoms are most preferred.

The water solubilizing polar group Z represents an anionic, a cationic, a non-ionic or ampholytic moiety or combinations thereof. Typical anionic groups would include COZH, COZM, SO2H, SOZM, SOBH, SO3M, OP(OH)2, and OP(OM)2, where M is a metallic ion, such as sodium, potassium, calcium, etc. Typical cationic groups would include NH2, NHR, where -R is a lower alkyl group such as methyl, ethyl or butyl, NR3'A, where R is a lower alkyl group or hydrogen and A is an anion, such as chloride, sulphate, phosphate, hydroxyl, etc. Typical non-ionic groups would include -NR2 O and those derived from polyethylene oxide and mixed polyethylene oxide-polypropylene oxide polyols. Typical mixed or ampholytic groups would include N(C2H4OH)2,

(C2H4CO2H)2-) O, and the like.

The linking group Qm, where m is an integer from O to 2, represents a multivalent, generally divalent, linking group such as alkylene, arylene, sulfonamido alkylene, carbonamido alkylene and the like. It will be noted that in some instances more than one Rf group may attach to a single Q group and in otherinstances, a single Rf group may be linked to more than one Q group, or may be linked by a single Q group to more than one polar solubilizing group.

With certain uorochemical surfactants, simple aqueous solutions thereof have been found to spread and form films on a hydrocarbon fuel surface. In general, however, such an aqueous fluorochemical surfactant solution, although the surface tension is below 28 or even below 20 dynes per centimeter, spreads slowly and does not provide a satisfactory lm. By utilizing the teachings of the present invention any such film-forming uorochemical-water solutions can be caused to provide a stable film, the inherent film-forming tendency of the uorochemical surfactant being enhanced by the addition of a compatible water-soluble fluorine-free surfactant. Compatibility here means that the two types of surfactants, fiuorine-containing and iiuorine-free, do not interact to produce an inactive product. That is, a nonionic uoroaliphatic surfactant can be mixed with a nonionic, an ionic, or a cationic fiuorine-free surfactant; similarly, a non-ionic fiuorine-free surfactant is compatible with all three classes of the uoroaliphatic surfactants. However, a cationic surfactant is not compatible with an anionic surfactant and such combinations must, in genfunction `of aqueous fiuoro-al-iphatic surfactant solutions. The particular nuoro-aliphatic surfactant having the structural formula shown did not form a surface film at any concentration, but with the addition of certain uorine-free surfactants, lms were formed as shown in the table. The formulation used for this table was as follows:

eral, be avoided if satisfactory film-forming characterisweight tics are to be realized. Percent The following tables graphically illustrate the rein- (l) forcing role of the iiuorine-free surfactant in the tlm- Cm, s O,N(C,H5) 02H40 1|) (OH)2 Q 36 forming characteristics of aqueous fluoroaliphatic surgliliorine-rleelsurratan m: o. Q5 factant solutions on a hydrocarbon fuel suiface, in this w-,' yf e g c -.1? aemailiii case cyclohexane.

TABLE 1 no FF concenconeen- Film properties 50% tration, tration, burnweiglit Fluorine-i'ree weight Speed, Seal, back, Fluorochemical surfactant, FC percent surfactant, FF percent Film sec. sec. sec.

C1Fi5CONHC3HN(CH3)z- O 0. 36 Yes... 12 15+ 3 Same as above 0. 09 Yes... 21 15-l 3 0. 023 N0 0. 023 Tetronic 904- 0. Yes. (l) 15 3 0.023 d0.. 0.09 YES... (1) 0 0 0. O23 Pluro c P-94. 0. 25 Yes. (l) 15 3 0.023 Aerosol OT 0. 25 Yes. 7 15+ 10 1 Very slow.

TABLE 2 FC FF coiicenconoen- Film properties tration, tration, bmw weight Fluorine-free weight Speed, Seul, back, Fluoi'ochemical surfactant, FC percent surfactant, FF percent Film sec. sec, Se@

C7Fi5CONHC3HeN+(C2H5)31'. 0. 36 Very slight Not covered 0 0 Same as above 0.36 Pluronic P-94 Yes.. 15+ 10 D0 0. 36 Tetronic 904. 25 5 Do 0. 36 Ammonyx LO. 25 3 [C7Fi5CONHC3HN+(CH3)3 0. 36 0 0 Same as above 0.36 Pluronic P-94 3 0 Do 0.36 Tetronic 904. 25 15 Do. 0.36 Tergito17. 3 3 D0. 0.36 Ammonyx LO. 15+ 9 CSF|7SO2N C2H5) 02H40 I (OHM 0. 36 Very slight... Not covered 0 0 Same as above 0.36 Pluronic P-94 6 0 Do 0. 36 R enex 31 0 0 C7F15CONHC3H0N CQHQ2C2H4C Il y C7FJ5COOH-N(CH3)2C3H6NHC:IH4COOH 0. 35 Tctronic 904 15+ 15 Same as above 0.36 Ammoiiyx SO. 15+ 25 NoTE.-Tetionic 904 is an ethylene diamine-propylene oxide-ethylene oxide adduct having the structural formula:

H(CgH.1O)y(C3H0O)x (C3HO)x(C2H4O)yH N CHzCHeN H C2H4o y o3ino)x (CaHeOhwzHiOMI with an ethylene oxide content of 40 percent and a molecular weight of 7,500.

TABLE 3 Examination of Table l will show that although the fluorochemical surfactant is capable of forming a fair Emulsl F111 Dropeftes bgg@ lm at relatively high concentrations, a superior lm is back,

formed at a concentration level where no ilm was formed by the aqueous fiuorochemical surfactant solution by the addition of an anionic lluorine-free surfactant, viz., Aerosol OT. The addition of other fluorine-fiee surfactants at the rio-film concentration of the fluorochemical surfactant also are shown to produce films comparing favorably with the film formed by the aqueous fluorochemical surfactant solution at much higher concentrations.

Table 2 presents further data confirming the results reported in Table l and illustrates the general nature of the present discovery, viz., that any film-forming fluorochemical surfactant water solution can be caused to provide a more durable and stable film in the presence of a compatible fluorine-free surfactant.

Table 3, illustrates in dramatic fashion the active .role assumed bythe fluorine-free surfactant in the nlm-forming Fluorine-free surfactant Triton X67 Pluronic P-94 at 0.15%.

As earlier noted, compositions according to the present invention were formulated with and without a stabilizer TABLE 3A Concen- Concen- Concen- Film properties Seal, burnback,

tration,

weight tration,

weight percent FF surfactant percent Stabilizer FC surfactant 0.016 IolyoxN-10.....

component. The following Table 3A graphically demonstrates the reinforcing effect of the stabilizer component in the characteristics of the formed films, The formulation for the compositions reported in this Table 3A included the components in the stated quantities, the remainder being water.

The film-promoting uorine-free surfactant must be Water-soluble in order to be satisfactorily applied, although, of course, an insoluble excess over a truly soluble amount can be dispersed within an aqueous carrier to be subsequently dissolved, foiexample, on dilution of a concentrateto the final film-forming solution. For convenience, however, the uorine-free surfactant should be water-soluble to at least about 0.02 percent by weight in water at 25 C., preferably 0.2 percent by weight. Insufficient solubility in the fuel phase results in no improvement in the spreading characteristics of the filmforming fiuorochemical surfactant-uorinefree surfactant aqueous solution, i.e., the fiuorine-free surfactant must be hydrocarbon-congruous. On the other hand, if the fluoriue-free surfactant is too soluble in the hydrocarbon fuel phase relative to the water phase, it will be rapidly removed and the film will collapse too rapidly to be useful. Suitable fluorine-free surfactants are characterized not so much by the absolute solubility of the material in the hydrocarbon fuel phase, as by the distribution of the material between the hydrocarbon fuel phase and the aqueous phase. As used herein, the term fiuorinefree refers to a compound which is free of uoroaliphatic radicals and contains no more than, at most, five percent carbon-bonded iluorine by weight.

In addition to being water-soluble and hydrocarboncongruous, as earlier noted, the organic uorine-free film-promoting surfactant of the present invention is also synthetic and imputrescible. Since the compositions of the present invention are intended to be stored, either in concentrate form or as dilute aqueous solutions, for' extended periods under varying environmental conditions it is highly desirable that the uorine-free surfactant component be non-putrifying to insure storage stability of the composition and, secondarily, provide for odorfree compositions in use. It has been found that certain synthetic organic compounds possess these qualities in addition to other qualities hereinbefore and hereafter set forth.

One method for selecting suitable fluorine-free surfactants is the determination of the efficiency of the surfactants in promoting aqueous emulsions of hydrocarbons in water. The test can be carried out very simply by adding to a standard container equal volumes of a test hydrocarbon, such as cyclohexane, and water together with a small amount of the fluorine-free surfactant to be tested. Agitation is started at a standard rate and the time determined at which the two-phase system acquires the high turbidity characteristic of an oil-in-water dispersion. Since the change from the coarse mixture to the uniform dispersion takes place over a very short period of time, this test develops into a very precise measurement. In general, fluorine-free surfactants which, under the below noted standard test conditions, provide an emulsion in 200 seconds or less also act to promote formation and spreading of films of fluoroaliphatic surfactant-water solutions on hydrocarbon substrates.

The test is carried out in a m1. breaker, 5 cm. in diameter x 6.5 cm. in height, equipped with a conventional magnetic stirrer bar 2.5 cm. in length and .95 cm. in average diameter. The stirrer used is obtainable from the Chicago Apparatus Co, under the trade name Magnastir. For each of the tests, 15 ml. each of distilled water and cyclohexane were used together with 0.25% by weight of the particular fluorine-free surfactant to be tested according to the following procedure:

(l) The water phase consists of distilled water containing 0.25% by weight of the uorine-free surfactant to be tested.

(2) The water phase is placed in the beaker followed by the careful addition of the cyclohexane phase.

(3) The .stirrer bar is introduced and rotated at a speed of 1250i250 r.p.rn.

(4) By using a light focused into the solution, the time in which an emulsion is formed is tested+this is indicated by a change in color from clear to white.

TABLE 4 Fluorine-free surfactant: Emulsion time seconds uorine-free surfactants which promoted the formation of useful vapor suppressing films either had emulsication times of 200 seconds or less or resulted in solutions which formed lms which spread over the cyclohexane surface in 60 seconds or less, or both.

Characteristically, addition of a water soluble electrolyte such as sodium chloride, magnesium sulphate and the like, to an aqueous surfactant solution tends to decrease the solubility of surfactants and not infrequently causes the surfactants to precipitate. Surprisingly, it has 10 C4H9CH(C2H5)C2H4CH(SO4N&) been found that the presence of an electrolyte dlssolved C2H4CH(C2IT5)2 in the water (even at concentrations as high as 7 percent (Tergtol 7, UUOII Carblde Chemlcal by weight or more) does not decrease the efficiency of Y Co.) 10 these uorine-free surfactant-fluoroaliphatic surfactant so- Polyoxyethylene ether alcohol (Renex 31;At 15 lutions. In many cases, it actually improves the filmlas Powder Co.) Y Y Y Y spreading characteristics. Not only doesthis simplify the Stearyl dimethyl amine oxide 200+ requirements for diluent water in making up film-forming Cetyl dimethyl amine oxide 200+ solutions for applications to fuel surfaces, but it allows Lauryl dimethyl amine oxide 200+ the use of these mixed surfactant solutions, for example, Myristyl dimethylamine oxide 120 20 on ships at sea where the only convenient diluent water Alkyl aryl sulfonate (Nacconol NR; Allled available is sea water with its relatively high salt con- Chemical Corp.) 150 tent. Dioctyl sodium sulfosuccinate In general, the ratio of uorine-free surfactant to fluoro- Dihexyl sodium sulfosuccinate 195 carbon surfactant is not critical. Weight ratios of 1:25 Diamyl sodium sulfosuccinate 198 25 to 10:1 are satisfactorily used, although the more usual C12H25N(CH3)2CH2CH2SO3 199 weight ratio falls between 1:15 to 5:1. Generally speakt-C12H25S(C2H4O)8 10H 30 ing, the ratio of uorine-free surfactants to uorine-con- Ammonium alkyl phenoxy polyoxyethyleneV taining surfactants is higher for those fluorine-free sursulfate (Alipal CO 436; General Aniline factants which are more soluble in hydrocarbon fuels;

and Film Corp.) 30 also, higher concentrations of iluorine-free surfactants Amphoteric fatty acid amido complex (Anare used Where the aqueous diluent will contain higher taron FC; General Aniline and Film concentrations of ionic materials. Either the uoroali- Corp.) 25 phatic or the fluorine-free surfactant or both may con- Phosphate ester of ahigher fatty alcohol mixsist of a mixture of two or more surface active mature (Gafac RS 710; General Aniline and terials.

Film Corp.) 15 The following Table 5 shows representative formula- CHH23COZN(CH2CH2OH)2 30 tions embodying the teachings of the present invention. Alkoxy polyoxyethylene oxyethanol (Triton The following base stock solution was used for each X `67 Rohm and Haas Co.) 200+ formulation: `Octylphenoxy polyoxyethylene oxyethanol (Triton X 100 Rohm and Haas Co.) 15 Parts Nonyi phenoxy polyoxyethyleneoxy ethanol Polyoxyethylene glycol, average NW 90,000 (PolyOX (Triton N 128 Rohm and Haas Co.) 15 N40) Sulfonated aliphatic hydrocarbon oil (Cal- CH3C02H 0.5

solene Oil HS; Imperial Chemical Indus- H0C2H4OH 30.0

tries) 200+ H2O 60.5 polyoxyethylene. ester? of mixed ahphatlc Test solutions were prepared by adding to the base stock carboxylic acids-011 soluble hydrocarbon th d f 1. h f d sulfonates (Witco 912' Witco Chemical e ieqmre amount o u oro? 1p am sur actant afl Co 200+ 0 iluorlne-free surfactant and dllutlng 6 ml. of the resultmg Tetro'nic 60 D solution with 94 ml. of either distilled water or sea water, as indicated. The sea water is a synthetic salt Another convenient method for selecting suitable fluomixture as defined by ASTM Test Method D 11.41-52 fille-free SUffaCaUS iS delefmllld by the F1101 Forma' dissolved in distilled water to a concentration of 42 grams tion and Spreading Test, above described. Those uorine- 55 per liter. free Surfactants Whlch When added to nonlm'frmmg The fluoroaliphatic surfactant for this table is a mixlluorocarbon surfactant solut1ons cause the resulting soture of 11 6 parts of lutions to form films which spread over the surface of the cyclohexane in seconds or less have been found C7F15CONHC3H6N+(CHSMCZHCOzto be satisfactory film-forming promoters. 60

Thus, examination of Table 3 will reveal that the and 1 part of C7F15CO2H-N(CH3)2C3H5NHC2H4CO2H.

TABLE 5 Concentration, weight percent 50% Fluoro- Fluorine- Agitation burnaliphatic free peed, Seal, resistance, back, Diluent Fluorine-tree surfactant surfactant surfactant sec. sec. sec. see.x

0. 36 15 0+ 10 3 Do-- P1uronieP-042 0.36 0.25 3 30+ 15+ 2 Do... Pluronio L-42..- 0.36 0.50 5 30+ 15+ 42 Do-- Pluronc 1,-64 0.36 0 50 3 30+ 15+ 21 Do 0.25 No3 30+ 7 3 Do- Pluronic F-77 0. 25 0. 18 15 30+ 15+ 13 Do Pluronie L-42 0.25 0.50 3 30+ 15+ 30 Do.- 0.18 No 30+ 1o 0 Do.- P1ur0nicL-12--- 0.18 0. 50 12 30+ 15+ 3s D0 Plumnic L-64 0.18 0.50 8 30+ 15+ 20 Footnotes lait end of table.

Table .5f-#Continued Concentration, weight percent 50% Fluoro- Fluorine- Agitation burntliphatic free Speed, Seal, resistance, back Diluent F111 rine-free surfactant surfactant surfactant sec. sec. sec. sec.1

Water 0.12 NC 0 U Do. Pluronie L-42 0. 12 NC 30+ 9 7 Do Pluronio L-M-- 0.12 NC 30+ 15+ 0 0. 12 N C 30+ 3 3 0. 36 12 30+ N R 9 0. 36 N C 0 N R 0 0. 36 2 30+ N R 36 0. 36 l 30+ NR 30 a.. 0. 36 3() 10 NR 9 C12H25N(CII5)2C2H4SO3. 0.36 4 30+ NR 7 O. 36 2 30+ NR 20 0. 36 2 30+ N R 15 0. 36 3 30+ N R 4 Sea wateiz 0. 36 0. 25 l 30+ NR 30 i 5 1 The violent agitation used in the Agitation Resistance Test disrupts the nlm. When the Burnback Test immediately follows the Agitation Resistance Test the times are therefore relatively shorter than when the Agitation Test is not run (NR).

2 Pluronic is a trademark of Wyandotte Chemical Co., Wyandotte, Michigan. The composition of thc indicated members of the series is believed to be as described in Table 6, following.

3 The symbol NC indicates that the film from 5 drops of solution does not expand to completely cover the Surface of the hydrocarbon under Test conditions, although drops forms a complete seal.

4 Renex 31 ls a trademark of Atlas Powder Co., Wilmington, Delaware, for a liquid polyoxycthylene ether alcohol nonionie surfactant.

Although anionic, cationic, amphoteric, and non-ionic fluorine-free surfactants are generally useful in the mixtures of this invention, it is particularly convenient to use nonionic fluorine-free surfactants because they are relatively insensitive to the effects of iluoroaliphatic surfactant structure or the ionic concentration of the aqueous solution and furthermore, are available in a Wide range of relative solubilities, making easy the selection of appropriate materials. One class of non-ionic fluorinefree surfactant which has proven particularly useful consists of the high molecular weight block copolymers of polyethylene oxide and polypropylene oxide (pluronics).

Ot this class, those with a polyethylene oxide content of 20 percent to 70 percent generally perform better than those with more or less polyethylene oxide. Those materials with a polypropylene oxide block of 1750 to 3250 molecular weight also show generally better performance than those with higher or lower block molecular weights. The following Table 6 lists some properties of this particular class of iluorine-free surfactants.

TABLE 6.-PR01 ERTIES oF PLURONIC SURFACTANTS 45 [Pluronics are HO(C2H40)(C3H6O)s(C2H4O)cH, block copolymers made by Wyandotte Chemical Coro] Emulsion Percent M.W; time,

02H40 (031160) seconds 50 Pluronic N o.:

L- 10 95o 200+ 950 200+ a0 050 200+ 20 1,200 200+ 40 1,200 200+ l0 1,750 l5 55 20 1,750 20 40 1,750 5 s0 1,750 200+ 20 2,050 5 50 2,050 15 2,050 200+ 10 2,250 1o 50 2,250 15 00 s0 2, 250 200+ 40 2,750 1o a0 2, 750 200+ 30 3, 250 40 50 3, 250 15 so 3,250 200+ In an effort to test the efficacy of a composition of the present invention on a large scale tire, a fire-fighting composition was formulated as follows:

Parts C6F13sO2NHC3H6N(CH3)2- O 4.0 C6F13SO2NHC3H6N(CH3)2 2.0 Renex 31 0.5 Butyl carbitol 25.0 Acetic acid 1.5

Water 67.0

This concentrate, diluted with sixteen parts water, was found to have a film speed of 15 seconds and a seal time of 180 seconds when tested on the surface of heptane.

The thus diluted aqueous solution was then comparatively tested on a 400 square feet (circular) white marine gasoline fire against the first composition shown in Table 5 which contained no fluorine-free surfactant. The test conditions and results were as follows:

FC FC-FF surfactant surfactant solution solution Time to extiuguishment, seconds 70 Burnback, seconds:

The foregoing large scale fire test results show, quite vividly, the effect achieved by the combination of the fluoroaliphatic surfactant and the Renex 31 watersoluble synthetic imputrescible organic iluorine-free surfactant. Thus, it will be observed that burnback times with the composition of the present invention are at least 3 to 6 times greater than the burn'back times of the solution containing only a fluoroaliphatic surfactant. Burnback times are quite critical in fighting petroleum fed fires, particularly those involving aircraft, since rescue personnel are dispatched through the flameextinguished areas at the earliest possible opportunity to effect personnel rescue. Obviously, the lives of the rescue personnel would be endangered if the fire-fighting composition did not afford a significant burnback time.

A primary limitation of previously known fire-fighting solutions involving fluorochemical surfactants and water, such as those described in Tuve and Jablonski U.S. Pat. No. 3,258,423, is that the fluorochemical component is used to provide both foaming and film-forming capability. This severely limits the choice of material which can be used. The present invention allows surfactant materials to be selected primarily on their ability for forming excellent vapor barrier films on fuel surfaces. If, in addition, foaming characteristics are desired, as for firefighting purposes, a foaming agent can be selected primarily on the basis of its foam producing and foam stability characteristics and used in conjunction with the film-forming agent. This foaming agent may be a fluorochemical surfactant, such as the perfluoroaliphatic carbonamido betaine suggested by Tuve and Jablonski or it may be a non-fluorinated foaming agent. One such common non-fluorinated foaming agent is the protein hydrolysate used to form the well known commercially available protein foam concentrates. Protein foam concentrates are well-known materials for producing aqueous foams in fire-fighting. Their preparation, formulation and use is described in the article, Fire-fighting Foams by l. M. Perri, page 189 of Foams-Theory and Industrial Applications, edited by J. J. Bikerman, Reinhold Publishing Corporation, New York, 1953. The concentrates are prepared by hydrolyzing any waste protein product such as soybean meal, hoofs, hair, feathers, or sh scales in either aqueous acid or aqueous base. Calcium hydroxide is a frequently used hydrolytic agent. Hydrolysis is normally carried out until a 25-35 percent aqueous solution has a viscosity below 100 centistokes at 7 C. This concentrate is usually mixed with about 16 parts by volume of water and 150 parts of gas, usually air, at the time of application to the fire.

Film forming solutions containing only a fluoroaliphatic surfactant usually harm the efficiency of a protein foam system, the mixture resulting in a thin and unstable foam blanket. It has been found that film forming mixtures including a compatible fluorine-free surfactant do not significantly harm the effectiveness of a protein foam used therewith. For use in conjunction with protein foams, non-ionic fluorine-free surfactants are preferred in combination with a cationic tiuorocarbon surfactant. In such uses, the protein foam-forming agent is normally used at to 10 times by weight of the fiuoroaliphatic surfactant and care must be taken to have the pH of the solution, either concentrate or final dispersion, within the range of 5 to 7 for optimum results.

The following Table 7 illustrates the flexibility which can be realized through the use of the teachings of the present invention in formulating foaming film forming compositions.

(static) and C-X (agitation) show the loss by evaporation of the cyclohexane when 0.00216 gram of is mixed into the cyclohexane.

FIG. 2 is a graph which shows the rate of evaporation of a 25 gram sample of cyclohexane contained in a Petri dish measuring 5 crn. in diameter by 2.7 cm. in height. Curve A represents the evaporation loss of the cyclohexane with 0.6 gram of an aqueous solution of 0.25 weight percent Pluronic P-94 placed on the surface. Curve B represents the evaporation rate of pure cyclohexane. Curves C (static) and C (agitation) show the evaporation rate of the cyclohexane with 0.6 gram of a 0.36 weight percent aqueous solution of placed on the surface of the cyclohexane. Curves D (static) and D (agitation) show the evaporation rate of the cyclohexane when covered with a vapor barrier film formed with 0.6 gram of an aqueous film-forming composition comprising 0.36 weight percent and 0.25 weight percent Pluronic P-94. Curve E represents the evaporation loss of the cyclohexane when gram Of (271315COlqfICIiI-Iglq'lh(C21-15h31q iS mixed into the cyclohexane.

What is claimed is:

1. A composition useful for suppressing vaporization of liquid hydrocarbons comprising water, a water-soluble fluoroaliphatic surfactant and a synthetic imputrescible hydrocarbon-congruous organic fluorine-free lm-promoting surfactant water-soluble to at least about 0.02 percent by weight in water at 25 C., said composition being substantially free from volatile flammable materials and being capable of forming a tough, durable, rapidly-forming and spreading film on the surface of the hydrocarbon thereby inhibiting the release of flammable vapors therefrom.

2. A composition useful for suppressing vaporization of flammable hydrocarbons, said composition being substantially free of water insoluble components and volatile TABLE 7.-PROTEIN FOAM FORMULATIONS Film properties Concen- Coneenurntration, i tration, Speed, Seal, back,

Fluorocarbon surfactant percent Fluorine-iree surfactant percent Compatibility sec. sec. sec.

Clear. .A (l) (l) (l) CFlgCONHCHENHm-w.. 0.18 Cloudy 18 15+ 4 Same 21S above 0. 12 [CH2N[(C3HGO)1u(C2H40)17H]e]2 0.03 Clear 6 15+ 22 C1F15CONHC3H6N(CHQzCgH/,COgzCFis 0. 36 Cloudy (2) 0 0 Same as above 0. 36 [CH2N[(C3HGO)19(C2H4O)17H]2]2 0. 25 Heavy residue. (3) 15+ 19 1 No film. 2 Very slow. 3 Slow.

FIG. 1 is a graph which shows the relative evaporation rates of 25 grams of cyclohexane contained in a Petri dish measuring 5 cm. in diameter by 2.7 cm. in height. Curves A-S and A-X show the evaporation rate of the cyclohexane under static conditions (AS) and with agitation of the cyclohexane for four hours (A-X) when 0.6 gram of a nlm-forming composition comprising 0.36 weight percent of C-,F15CONHC3H6N(CH3)2 O and Water was placed on the cyclohexane surface. Curves B-S (static) and B-X (agitation) show the evaporation rate of the cyclohexane with a vapor barrier film according to the invention placed thereover-the film was formed with 0.6 gram of an aqueous composition comprising 0.36 weight percent of C7F15CONHC3H6N 2 9 O and 0.25 weight percent Pluronic P-94. Curves C-S RfQmZ wherein Rf is a fluorinated saturated monovalent non-aromatic radical containing from 3 to 20 carbon atoms in which the carbon atoms of the chain are substituted only by uorine, chlorine or hydrogen atoms with no more than one hydrogen or chlorine atom for a very two carbon atoms, and in which a divalent oxygen or trivalent nitrogen atom, bonded only to carbon atoms, can be present in the skeletal chain;

Qm, where m is an integer from 0 to 2, is a multivalent linking group comprising alkylene, arylene, sulfonamido alkylene and carbonamido alkylene radicals; and

Z is a vwater solubilizing polar group comprising anionic,

cationic, non-ionic and ampholytic radicals.

4. A composition according to claim 3 wherein the uorine-free hlm-promoting surfactant is water-soluble to at least about 0.02 percent by weight in water at 25 C. and is capable of promoting the film-forming ability of a normally non-lm-forming aqueous uorocarbon surfactant solution so that the resulting solution forms a vapor suppressing film on the surface of a hydrocarbon liquid in no more than about 60 seconds.

5. A composition according to claim 4 wherein the fluorine-free nlm-promoting surfactant has an emulsification time, as herein defined, of no more than about 200 seconds.

6. A composition according to claim 1 additionally including a water-soluble inorganic electrolyte.

7. A composition according to claim 1 additionally including a partially hydrolyzed protein.

8. An aqueous solution according to claim 1 comprising a water-soluble uoroaliphatic surfactant and a watersoluble synthetic imputrescible hydrocarbon-congruous organic uorine-free nlm-promoting surfactant which is capable of 'being diluted with about sixteen parts by volume of water to provide a vapor-suppressing, film-forming composition.

9. A method of suppressing the vaporization of a volatile hydrocarbon liquid comprising applying the lmforming composition of claim 1 onto the surface of said hydrocarbon liquid and forming a tough, durable Vapor barrier lm on said surface.

10. A method of extinguishing a liquid hydrocarbon re comprising applying the nlm-forming composition of claim 1 onto the burning surface of said liquid hydrocarbon and forming a tough, durable vapor barrier film on said surface thereby inhibiting the further release of combustible vapors therefrom.

11. A method of extinguishing a liquid hydrocarbon fire comprising applying the film-forming composition of claim 6 onto the burning surface of said liquid hydrocarbon and forming a tough, durable vapor barrier lm on said surface thereby inhibiting the further release of combustible vapors therefrom.

12. A method of extinguishing a liquid hydrocarbon lire comprising applying the lm-forming composition of claim 8 onto the burning surface of said liquid hydrocarbon and forming a tough, durable vapor barrier film on said surface thereby inhibiting the further releaseof combustible vapors therefrom.

References Cited UNITED STATES PATENTS 6/1966 Tuve et al. 252-8.05X l1/l967 Meldrum et al. 252-3 

